Projectile

A projectile is an object that is propelled by the application of an external force and then moves freely under the influence of gravity and air resistance. Although any objects in motion through space are projectiles, they are commonly found in warfare and sports (for example, a thrown baseball, kicked football, fired bullet, shot arrow, stone released from catapult).

In ballistics, mathematical equations of motion are used to analyze projectile trajectories through launch, flight, and impact.

Motive force

Projectile and cartridge case for the huge World War II **Schwerer Gustav** artillery piece. Most projectile weapons use the compression or expansion of gases as their motive force.

Blowguns and pneumatic rifles use compressed gases, while most other guns and cannons utilize expanding gases liberated by sudden chemical reactions by propellants like smokeless powder. Light-gas guns use a combination of these mechanisms.

Railguns utilize electromagnetic fields to provide a constant acceleration along the entire length of the device, greatly increasing the muzzle velocity.

Some projectiles provide propulsion during flight by means of a rocket engine or jet engine. In military terminology, a rocket is unguided, while a missile is guided. Note the two meanings of "rocket" (weapon and engine): an ICBM is a guided missile with a rocket engine.

An explosion, whether or not by a weapon, causes the debris to act as multiple high velocity projectiles. An explosive weapon or device may also be designed to produce many high velocity projectiles by the break-up of its casing; these are correctly termed fragments.

In sports

Ball speeds of 105 miles per hour (169 km/h) have been recorded in **baseball**.

In projectile motion the most important force applied to the ‘projectile’ is the propelling force, in this case the propelling forces are the muscles that act upon the ball to make it move, and the stronger the force applied, the more propelling force, which means the projectile (the ball) will travel farther. See pitching, bowling.

As a weapon

Delivery projectiles

Many projectiles, e.g. shells, may carry an explosive charge or another chemical or biological substance. Aside from explosive payload, a projectile can be designed to cause special damage, e.g. fire (see also early thermal weapons), or poisoning (see also arrow poison).

Kinetic projectiles

The **Homing Overlay Experiment** used a metal fan that was rolled up during launch and expanded during flight. The metal has five times as much destructive power as an explosive warhead of the same weight.

Sample from a kinetic energy weapon test. A piece of **polycarbonate** plastic weighing 7 grams (1⁄4 oz) was fired at an **aluminium** block at 7 km/s (23,000 ft/s), giving it **muzzle energy** of 171,500 J (126,500 ft⋅lbf); a typical **bullet** has muzzle energy of a few thousand joules, with the enormous **.950 JDJ** reaching 20,000 J (15,000 ft⋅lbf).

A kinetic energy weapon (also known as kinetic weapon, kinetic energy warhead, kinetic warhead, kinetic projectile, kinetic kill vehicle) is a projectile weapon based solely on a projectile's kinetic energy to inflict damage to a target, instead of using any explosive, incendiary/thermal, chemical or radiological payload. All kinetic weapons work by attaining a high flight speed — generally supersonic or even up to hypervelocity — and collide with their targets, converting their kinetic energy and relative impulse into destructive shock waves, heat and cavitation. In kinetic weapons with unpowered flight, the muzzle velocity or launch velocity often determines the effective range and potential damage of the kinetic projectile.

Kinetic weapons are the oldest and most common ranged weapons used in human history, with the projectiles varying from blunt projectiles such as rocks and round shots, pointed missiles such as arrows, bolts, darts, and javelins, to modern tapered high-velocity impactors such as bullets, flechettes, and penetrators. Typical kinetic weapons accelerate their projectiles mechanically (by muscle power, mechanical advantage devices, elastic energy or pneumatics) or chemically (by propellant combustion, as with firearms), but newer technologies are enabling the development of potential weapons using electromagnetically launched projectiles, such as railguns, coilguns and mass drivers. There are also concept weapons that are accelerated by gravity, as in the case of kinetic bombardment weapons designed for space warfare.

The term hit-to-kill, or kinetic kill, is also used in the military aerospace field to describe kinetic energy weapons accelerated by a rocket engine. It has been used primarily in the anti-ballistic missile (ABM) and anti-satellite weapon (ASAT) fields, but some modern anti-aircraft missiles are also kinetic kill vehicles. Hit-to-kill systems are part of the wider class of kinetic projectiles, a class that has widespread use in the anti-tank field.

Wired projectiles

Some projectiles stay connected by a cable to the launch equipment after launching it:

for guidance: wire-guided missile (range up to 4,000 metres or 13,000 feet)
to administer an electric shock, as in the case of a Taser (range up to 10.6 metres or 35 feet); two projectiles are shot simultaneously, each with a cable.
to make a connection with the target, either to tow it towards the launcher, as with a whaling harpoon, or to draw the launcher to the target, as a grappling hook does.

Typical projectile speeds

Projectile	Speed				Specific kinetic energy (J/kg)
Projectile	(m/s)	(km/h)	(ft/s)	(mph)	Specific kinetic energy (J/kg)
Object falling 1 m (in vacuum, at Earth's surface)	4.43	15.948	14.5	9.9	9.8
Object falling 10 m (in vacuum, at Earth's surface)	14	50.4	46	31	98
Thrown club (expert thrower)	40	144	130	90	800
Object falling 100 m (in vacuum, at Earth's surface)	45	162	150	100	980
Refined (flexible) atlatl dart (expert thrower)	45	162	150	100	1,000
Ice hockey puck (slapshot, professional player)	50	180	165	110	1,300
80-lb-draw pistol crossbow bolt	58	208.8	190	130	1,700
War arrow shot from a 150 lbs medieval warbow	63	228.2	208	141	2,000
shot from a 40mm grenade launcher	87	313.2	285	194.6	3,785
Paintball fired from marker	91	327.6	300	204	4,100
175-lb-draw crossbow bolt	97	349.2	320	217	4,700
6 mm Airsoft pellet	100	360	328	224	5,000
BB 4.5 mm	150	540	492	336	11,000
Air gun pellet .177" (magnum-power air rifle)	305	878.4	1,000	545	29,800
9×19mm (bullet of a pistol)	340	1224	1,116	761	58,000
12.7×99 mm (bullet of a heavy machine gun)	800	2,880	2,625	1,790	320,000
German Tiger I 88 mm (tank shell- Pzgr. 39 APCBCHE)	810	2,899	2,657	1,812	328,050
5.56×45mm (standard round used in many modern rifles)	920	3,312	3,018	2,058	470,000
20×102mm (standard US cannon round used in fighter cannons)	1,039	3,741	3,410	2,325	540,000
25×140mm (APFSDS, tank penetrator)	1,700	6,120	5,577	3,803	1,400,000
2 kg tungsten Slug (from Experimental Railgun)	3,000	10,800	9,843	6,711	4,500,000
MRBM reentry vehicle	Up to 4,000	Up to 14,000	Up to 13,000	Up to 9,000	Up to 8,000,000
projectile of a light-gas gun	Up to 7,000	Up to 25,000	Up to 23,000	Up to 16,000	Up to 24,000,000
Satellite in low Earth orbit	8,000	29,000	26,000	19,000	32,000,000
Exoatmospheric Kill Vehicle	~10,000	~36,000	~33,000	~22,000	~50,000,000
Projectile (e.g., space debris) and target both in low Earth orbit	0–16,000	~58,000	~53,000	~36,000	~130,000,000
7 TeV particle in LHC	299,792,455	1,079,252,839	983571079	670,616,536	~6.7 × 10²⁰

Equations of motion

An object projected at an angle to the horizontal has both the vertical and horizontal components of velocity. The vertical component of the velocity on the y-axis is given as $V_{y}=U\sin \theta$ while the horizontal component of the velocity is $V_{x}=U\cos \theta$ . There are various calculations for projectiles at a specific angle $\theta$ :

1. Time to reach maximum height. It is symbolized as ( $t$ ), which is the time taken for the projectile to reach the maximum height from the plane of projection. Mathematically, it is given as $t=U\sin \theta /g$ where $g$ = acceleration due to gravity (app 9.81 m/s²), $U$ = initial velocity (m/s) and $\theta$ = angle made by the projectile with the horizontal axis.

2. Time of flight ( $T$ ): this is the total time taken for the projectile to fall back to the same plane from which it was projected. Mathematically it is given as $T=2U\sin \theta /g$ .

3. Maximum Height ( $H$ ): this is the maximum height attained by the projectile OR the maximum displacement on the vertical axis (y-axis) covered by the projectile. It is given as $H=U^{2}\sin ^{2}\theta /2g$ .

4. Range ( $R$ ): The Range of a projectile is the horizontal distance covered (on the x-axis) by the projectile. Mathematically, $R=U^{2}\sin 2\theta /g$ . The Range is maximum when angle $\theta$ = 45°, i.e. $\sin 2\theta =1$ .

Notes

Approximate equivalent of 99,9999991% c.
In relation to the rest mass of proton.

References

Pius, Okeke; Maduka, Anyakoha (2001). Senior Secondary School Physics. Macmillan,Lagos, Nigeria.
"projectile". merriam-webster.com. Retrieved 13 April 2017.
"projectile". The Free Dictionary. Retrieved 2010-05-19.
"projectile". Dictionary.com. Retrieved 2010-05-19.
Pepin, Matt (2010-08-26). "Aroldis Chapman hits 105 mph". Boston.com. Archived from the original on 31 August 2010. Retrieved 2010-08-30.
"Facts and figures". European Organization for Nuclear Research. CERN. 2008. Archived from the original on 2018-07-02. Retrieved 2018-07-02.

Heidi Knecht (29 June 2013). Projectile Technology. Springer Science & Business Media. ISBN 978-1-4899-1851-2.

External links

Open Source Physics computer model
Projectile Motion Applet
Another projectile Motion Applet

[7] Approximate equivalent of 99,9999991% c.

[8] In relation to the rest mass of proton.

[1] Pius, Okeke; Maduka, Anyakoha (2001). Senior Secondary School Physics. Macmillan,Lagos, Nigeria.

[2] "projectile". merriam-webster.com. Retrieved 13 April 2017.

[3] "projectile". The Free Dictionary. Retrieved 2010-05-19.

[4] "projectile". Dictionary.com. Retrieved 2010-05-19.

[5] Pepin, Matt (2010-08-26). "Aroldis Chapman hits 105 mph". Boston.com. Archived from the original on 31 August 2010. Retrieved 2010-08-30.

[6] "Facts and figures". European Organization for Nuclear Research. CERN. 2008. Archived from the original on 2018-07-02. Retrieved 2018-07-02.